The molecular weight of the basic polypetide chain αB2 of α-crystallin

The molecular weights calculated from the amino acid sequences of the A and B chains of the lens protein -crystallin differ only slightly (19830 and 20070, respectively). SDS gel electrophoresis of these chains and comparison with marker proteins yield apparent molecular weights of 19500 for A and 22500 for B. The discrepancy between the value of 22500 and the real molecular weight of 20070 for B vanishes by the combined use of SDS and 6 M urea in the polyacrylamide gels.     

In vitro interactions of histones and α-crystallin

The aggregation of crystallins in lenses is associated with cataract formation. We previously reported that mutant crystallins are associated with an increased abundance of histones in knock-in and knockout mouse models. However, very little is known about the specific interactions between lens crystallins and histones. Here, we performed in vitro analyses to determine whether α-crystallin interacts with histones directly. Isothermal titration calorimetry revealed a strong histone–α-crystallin binding with a K_d of 4 × 10^?7 M, and the thermodynamic parameters suggested that the interaction was both entropy and enthalpy driven. Size-exclusion chromatography further showed that histone–α-crystallin complexes are water soluble but become water insoluble as the concentration of histones is increased. Right-angle light scattering measurements of the water-soluble fractions of histone–α-crystallin mixtures showed a decrease in the oligomeric molecular weight of α-crystallin, indicating that histones alter the oligomerization of α-crystallin. Taken together, these findings reveal for the first time that histones interact with and affect the solubility and aggregation of α-crystallin, indicating that the interaction between α-crystallin and histones in the lens is functionally important.     

The benefits of being β-crystallin heteromers: βB1-crystallin protects βA3-crystallin against aggregation during co-refolding

β-Crystallins are the major structural proteins in mammalian lens, and their stability is critical in maintaining the transparency and refraction index of the lens. Among the seven β-crystallins, βA3-crystallin and βB1-crystallin, an acidic and a basic β-crystallin, respectively, can form heteromers in vivo. However, the physiological roles of the heteromer have not been fully elucidated. In this research, we studied whether the basic β-crystallin facilitates the folding of acidic β-crystallin. Equilibrium folding studies revealed that the βA3-crystallin and βB1-crystallin homomers and the βA3/βB1-crystallin heteromer all undergo similar five-state folding pathways which include one dimeric and two monomeric intermediates. βA3-Crystallin was found to be the most unstable among the three proteins, and the transition curve of βA3/βB1-crystallin was close to that of βB1-crystallin. The dimeric intermediate may be a critical determinant in the aggregation process and thus is crucial to the lifelong stability of the β-crystallins. A comparison of the Gibbs free energy of the equilibrium folding suggested that the formation of heteromer contributed to the stabilization of the dimer interface. On the other hand, βA3-crystallin, the only protein whose refolding is challenged by serious aggregation, can be protected by βB1-crystallin in a dose-dependent manner during the kinetic co-refolding. However, the protection is not observed in the presence of the pre-existed well-folded βB1-crystallin. These findings suggested that the formation of β-crystallin heteromers not only stabilizes the unstable acidic β-crystallin but also protects them against aggregation during refolding from the stress-denatured states.     

Predicting the molecular interactions of CRIP1a–cannabinoid 1 receptor with integrated molecular modeling approaches

Cannabinoid receptors are a family of G-protein coupled receptors that are involved in a wide variety of physiological processes and diseases. One of the key regulators that are unique to cannabinoid receptors is the cannabinoid receptor interacting proteins (CRIPs). Among them CRIP1a was found to decrease the constitutive activity of the cannabinoid type-1 receptor (CB₁R). The aim of this study is to gain an understanding of the interaction between CRIP1a and CB₁R through using different computational techniques. The generated model demonstrated several key putative interactions between CRIP1a and CB₁R, including the critical involvement of Lys130 in CRIP1a.     

Binding of γ-crystallin substrate prevents the binding of copper and zinc ions to the molecular chaperone α-crystallin

α-Crystallin is a small heat shock protein and molecular chaperone. Binding of Cu2+ and Zn2+ ions to α-crystallin leads to enhanced chaperone function. Sequestration of Cu2+ by α-crystallin prevents metal-ion mediated oxidation. Here we show that binding of human γD-crystallin (HGD, a natural substrate) to human αA-crystallin (HAA) is inversely related to the binding of Cu2+/Zn2+ ions: The higher the amount of bound HGD, the lower the amount of bound metal ions. Thus, in the aging lens, depletion of free HAA will not only lower chaperone capacity but also lower Cu2+ sequestration, thereby promoting oxidation and cataract.     

Novel enzymological profiles of human 11β-hydroxysteroid dehydrogenase type 1

The human enzyme 11β-hydroxysteroid dehydrogenase (11β-HSD) catalyzes the reversible oxidoreduction of 11β-OH/11-oxo groups of glucocorticoid hormones. Besides this important endocrinological property, the type 1 isozyme (11β-HSD1) mediates reductive phase I reactions of several carbonyl group bearing xenobiotics, including drugs, insecticides and carcinogens. The aim of this study was to explore novel substrate specificities of human 11β-HSD1, using heterologously expressed protein in the yeast system Pichia pastoris. In addition to established phase I xenobiotic substrates, it is now demonstrated that transformed yeast strains catalyze the reduction of ketoprofen to its hydroxy metabolite, and the oxidation of the prodrug DFU-lactol to the pharmacologically active lactone compound. Purified recombinant 11β-HSD1 mediated oxidative reactions, however, the labile reductive activity component could not be maintained. In conclusion, evidence is provided that human 11β-HSD1 in vitro is involved in phase I reactions of anti-inflammatory non-steroidal drugs like ketoprofen and DFU-lactol.     

Direct molecular interactions between Beclin 1 and the canonical NFκB activation pathway

General (macro)autophagy and the activation of NFκB constitute prominent responses to a large array of intracellular and extracellular stress conditions. The depletion of any of the three subunits of the inhibitor of NFκB (IκB) kinase (IKKα, IKKβ, IKKγ/NEMO), each of which is essential for the canonical NFκB activation pathway, limits autophagy induction by physiological or pharmacological triggers, while constitutive active IKK subunits suffice to stimulate autophagy. The activation of IKK usually relies on TGFβ-activated kinase 1 (TAK1), which is also necessary for the optimal induction of autophagy in multiple settings. TAK1 interacts with two structurally similar co-activators, TAK1-binding proteins 2 and 3 (TAB2 and TAB3). Importantly, in resting conditions both TAB2 and TAB3 bind the essential autophagic factor Beclin 1, but not TAK1. In response to pro-autophagic stimuli, TAB2 and TAB3 dissociate from Beclin 1 and engage in stimulatory interactions with TAK1. The inhibitory interaction between TABs and Beclin 1 is mediated by their coiled-coil domains (CCDs). Accordingly, the overexpression of either TAB2 or TAB3 CCD stimulates Beclin 1- and TAK1-dependent autophagy. These results point to the existence of a direct molecular crosstalk between the canonical NFκB activation pathway and the autophagic core machinery that guarantees the coordinated induction of these processes in response to stress.     

Specific dissociation of αB subunits from α-crystallin

Exposure of bovine α-crystallin to 0.1 M glycine at pH 7 decreases the average molar mass of the protein from 700 to 420 kDa. When the pH is lowered to 2.5, in the same buffer, the αB chains specifically dissociate from the aggregates, leaving a particle of 290 kDa containing only αA chains. The decrease in the molar mass corresponds to the mass of the αB chains in the original aggregate. The pH-dependent dissociation is fully reversible. Similar changes were observed with rat and kangaroo α-crystallins but the dogfish protein was not affected. Sedimentation velocity analyses and fluorescence spectroscopy yielded a pK, for the dissociation, of 3.7 for α-crystallin and 4.0 for a homopolymer constructed from purified αB₂ polypeptides. An αA₂ homopolymer was virtually unaffected by the lowering of pH. The products from the dissociation were isolated and their properties studied by sedimentation analysis and acrylamide quenching of tryptophan fluorescence. The αB chains were found to be completely denatured, whereas the structure of the αA chains, in the 290 kDa, particle, were only slightly altered. Comparisons of the sequences of the various proteins examined suggested that decreased ionization of aspartic acid 127 in the αB chain was responsible for the specific dissociation of this polypeptide.     

Analysis of the molecular interactions of the potent analgesic S1RA with the σ1 receptor

The highly selective σ₁ receptor antagonist S1RA is endowed with a surprisingly high affinity for its target protein given a missing fundamental hydrophobic pharmacophoric requirement. Here we show that, with respect to other potent σ₁ ligands, S1RA is able to compensate this loss by fulfilling all other pharmacophoric requirements and by gaining in solvation energy     

β-Strand-mediated interactions of protein domains

Protein domains exist by themselves or in combination with other domains to form complex multidomain proteins. Defining domain boundaries in proteins is essential for understanding their evolution and function but is not trivial. More specifically, partitioning domains that interact by forming a single β-sheet is known to be particularly troublesome for automatic structure-based domain decomposition pipelines. Here, we study edge-to-edge β-strand interactions between domains in a protein chain, to help define the boundaries for some more difficult cases where a single β-sheet spanning over two domains gives an appearance of one. We give a number of examples where β-strands belonging to a single β-sheet do not belong to a single domain and highlight the difficulties of automatic domain parsers on these examples. This work can be used as a baseline for defining domain boundaries in homologous proteins or proteins with similar domain interactions in the future.     

Phylogenetic profiles for the prediction of protein-protein interactions: how to select reference organisms?

The phylogenetic profile method has been widely applied in the prediction of protein-protein interactions (PPIs). Studies often use all of the available complete genomes for this method. With more than 400 genomes complete and new ones on the horizon, it remains unclear how to select reference organisms for profile construction and then influence the PPI prediction. Here, we performed a systematic assessment of reference organism selection from 225 complete genomes with their evolutionary tree. Our results suggest that reference organisms should be selected from moderately and highly genetically distant organisms, from all three domains (Bacteria, Archaea, and Eukarya), and by their even distribution at the fifth hierarchical level in the evolutionary tree. Our study provides important guidance on the construction of phylogenetic profiles for PPI prediction and functional genomics, which has become challenging due to the large and increasing number of available candidate organisms.     

Kinetics and thermodynamic transitions of N-acetyl-β-D-glucosaminidase A and B in free and bound forms: Role of cellulose ion-exchangers

Summary The kinetic and thermodynamic properties of N-acetyl--D-glucosaminidase A (Hex A) and N-acetyl--D-D-glucosaminidase (Hex B) from goat testes were investigated in free and bound (after binding them on ion-exchangers such as DEAE- or CM-cellulose respectively) forms. The optimum pH of free Hex A and Hex B was at 4.2 and 5.4, whereas the bound forms showed the optimum pH at 4.0 and 5.2 respectively. While apparent K_m of free and bound Hex A (0.8 and 1.0 mM respectively) did not differ, the K_m of Hex B increased when bound on CM-cellulose (K_m of free Hex B = 0.96 mM versus bound Hex B = 1.6 mM). Though the free Hex A was more thermo-labile than the free Hex B, both isozymes, on insoluble matrices decayed at faster rates on heating. Activation analysis revealed that the energy of activation (E _infa ^supo ) for transition state of free Hex B (81 Kcal deg^–1 mole^–1) did not differ from E _infa ^supo of bound Hex B. On the other hand, E _infa ^supo of free Hex A declined from 77.2 to 71.1 Kcal deg^–1 mole^–1 when heat transitions were carried out in free and bound state respectively. Thermodynamic analysis suggested a change in entropy of activation (S^*) of free Hex A and Hex B as 200 and 211 eu respectively. While S^* of Hex B did not change after heat transitions, S^* of Hex A was 182.5 eu.     

Structure and behavior of human α-thrombin upon ligand recognition: thermodynamic and molecular dynamics studies

Thrombin is a serine proteinase that plays a fundamental role in coagulation. In this study, we address the effects of ligand site recognition by alpha-thrombin on conformation and energetics in solution. Active site occupation induces large changes in secondary structure content in thrombin as shown by circular dichroism. Thrombin-D-Phe-Pro-Arg-chloromethyl ketone (PPACK) exhibits enhanced equilibrium and kinetic stability compared to free thrombin, whose difference is rooted in the unfolding step. Small-angle X-ray scattering (SAXS) measurements in solution reveal an overall similarity in the molecular envelope of thrombin and thrombin-PPACK, which differs from the crystal structure of thrombin. Molecular dynamics simulations performed with thrombin lead to different conformations than the one observed in the crystal structure. These data shed light on the diversity of thrombin conformers not previously observed in crystal structures with distinguished catalytic and conformational behaviors, which might have direct implications on novel strategies to design direct thrombin inhibitors.     

Armchair BN nanotubes—levothyroxine interactions: a molecular study

The density functional theory has been applied to investigate the structural and electronic properties of single-wall boron nitride nanotubes (SW-BNNT) of (5,5) chirality, with surface and ends functionalized by the drug levothyroxine (C₁₅H₁₁NI₄O₄). The exchange-correlation energies have been modeled according to the Hamprecht-Cohen-Tozer-Handy functional within the generalized gradient approximation (HCTH-GGA) and a base function with double polarization has been used. The (5,5) BNNT-Levothyroxine structural optimization has been done considering the minimum energy criterion in nine possible atomic structures. Simulation results indicate that the preferential adsorption site (chemical adsorption) of the levothyroxine fragment is at the nanotube ends. The BNNT-Levothyroxine system polarity increases which indicates the possible dispersion and solubility both non-solvated and solvated in water. The BNNT-Levothyroxine solvated in water modifies its chemical reactivity which may allow the drug delivery within the biological systems. On the other hand, the decrease in the work function is important for the optoelectronic device design, which also makes these materials suitable to improve the field emission properties.     

Interaction of detergents with bovine lens α-crystallin: evidence for an oligomeric structure based on amphiphilic interactions

We have studied the quaternary structure of α-crystallin in the presence of increasing concentrations of amphiphilic and neutral detergents using gel filtration, light-scattering, boundary and equilibrium sedimentation. We observed a continuous reduction of the molar mass of the polymeric α-crystallin on increasing the concentration of sodium dodecyl sulphate from 0.1 mM to 5 mM, ending up with the monomeric peptides. Dodecyltrimethylammonium bromide also disrupts the oligomeric structure of α-crystallin but the interaction appears to be cooperative: in the sharp transition region (for a 1 mg/ml protein solution) from 3 to 8 mM of the detergent, only the native protein and a mixture of monomeric and dimeric peptide-DTAB complexes can be observed. Concomitant studies of the circular dichroism in the far UV revealed a substantial decrease of the β-sheet and increase of the α-helix secondary structure. The latter can be related to the presence of amphiphilic polypeptide sequences in the constituent αA and αB peptides. These studies reveal for the first time a direct relation between changes in the secondary structure of the αA and αB peptides and the formation of the oligomeric α-crystallin structure: the binding of the amphiphilic detergent reduces the β-sheet content, induces the formation of α-helix secondary structure and reduces the tendency of the peptide to form large aggregates. The different mechanisms for reducing the oligomeric size by anionic and cationic detergents with identical apolar parts stresses the importance of charge interactions. Our findings support some aspects of the micelle model of α-crystallin and can be related to its chaperone activity. Accepted: 18 October 1996     

Intracellular antibody capture: A molecular biology approach to inhibitors of protein–protein interactions

Many proteins of interest in basic biology, translational research studies and for clinical targeting in diseases reside inside the cell and function by interacting with other macromolecules. Protein complexes control basic processes such as development and cell division but also abnormal cell growth when mutations occur such as found in cancer. Interfering with protein–protein interactions is an important aspiration in both basic and disease biology but small molecule inhibitors have been difficult and expensive to isolate. Recently, we have adapted molecular biology techniques to develop a simple set of protocols for isolation of high affinity antibody fragments (in the form of single VH domains) that function within the reducing environment of higher organism cells and can bind to their target molecules. The method called Intracellular Antibody Capture (IAC) has been used to develop inhibitory anti-RAS and anti-LMO2 single domains that have been used for target validation of these antigens in pre-clinical cancer models and illustrate the efficacy of the IAC approach to generation of drug surrogates. Future use of inhibitory VH antibody fragments as drugs in their own right (we term these macrodrugs to distinguish them from small molecule drugs) requires their delivery to target cells in vivo but they can also be templates for small molecule drug development that emulate the binding sites of the antibody fragments. This article is part of a Special Issue entitled: Recent advances in molecular engineering of antibody.     

The interactions of molecular chaperones with client proteins: why are they so weak?

The major classes of molecular chaperones have highly variable sequences, sizes, and shapes, yet they all bind to unfolded proteins, limit their aggregation, and assist in their folding. Despite the central importance of this process to protein homeostasis, it has not been clear exactly how chaperones guide this process or whether the diverse families of chaperones use similar mechanisms. For the first time, recent advances in NMR spectroscopy have enabled detailed studies of how unfolded, “client” proteins interact with both ATP-dependent and ATP-independent classes of chaperones. Here, we review examples from four distinct chaperones, Spy, Trigger Factor, DnaK, and HscA-HscB, highlighting the similarities and differences between their mechanisms. One striking similarity is that the chaperones all bind weakly to their clients, such that the chaperone–client interactions are readily outcompeted by stronger, intra- and intermolecular contacts in the folded state. Thus, the relatively weak affinity of these interactions seems to provide directionality to the folding process. However, there are also key differences, especially in the details of how the chaperones release clients and how ATP cycling impacts that process. For example, Spy releases clients in a largely folded state, while clients seem to be unfolded upon release from Trigger Factor or DnaK. Together, these studies are beginning to uncover the similarities and differences in how chaperones use weak interactions to guide protein folding.     

A re-evaluation of the molecular size of duck ε-crystallin and its comparison with avian lactate dehydrogenases

A biochemical comparison of ε-crystallin isolated from the duck lens and lactate dehydrogenase of chicken heart has been made in order to establish the structural and functional identities of these two proteins. The native molecular weight of ε-crystallin was re-examined by combining sedimentation and gel-filtration data. It was found that ε-crystallin is 150 kDa in contrast to the 120 kDa reported previously for this crystallin. Subunit cross-linking experiments corroborated that lactate dehydrogenase and ε-crystallin both exist as tetramers of four identical subunits in their native quaternary structures. Amino acid compositions plus N-terminal analyses revealed no differences between the two proteins. Duck ε-crystallin exhibited high enzymatic activity of lactate dehydrogenases even after a long period of storage, and showed characteristic thermostability at 50°C for several hours. Comparison of the enzyme activity of duck lens homogenate with those of heart, liver and muscle tissues revealed that duck lens is a much richer source than other tissues for the isolation and characterization of this important enzyme which appears also as a structural protein in the lens.     

Disulfide cross-links in the interaction of a cataract-linked αA-crystallin mutant with βB1-crystallin

A number of αA-crystallin mutants are associated with hereditary cataract including cysteine substitution at arginine 49. We report the formation of affinity-driven disulfide bonds in the interaction of αA-R49C with βB1-crystallin. To mimic cysteine thiolation in the lens, βB1-crystallin was modified by a bimane probe through a disulfide linkage. Our data suggest a mechanism whereby a transient disulfide bond occurs between αA- and βB1-crystallin followed by a disulfide exchange with cysteine 49 of a neighboring αA-crystallin subunit. This is the first investigation of disulfide bonds in the confine of the chaperone/substrate complex where reaction rates are favored by orders of magnitude. Covalent protein cross-links are a hallmark of age-related cataract and may be a factor in its inherited form.